DISPLAY SCREEN HAVING REGIONS OF DIFFERING PIXEL DENSITY
A display device including: a display screen having first region and second region, the first region having a first pixel density and the second region having a second pixel density, the second pixel density being higher than the first pixel density, an input for receiving image data, a power source; and wherein the display screen is operable in a full screen mode in which an image is displayed in both the first region and the second region and a reduced screen mode in which power to the first region is turned off and the image is displayed in the second region.
present embodiments relate to display screens.
BACKGROUNDWhen operating any type of electronic device having a display screen (which may be referred to for convenience as a “display device”), it is desirable to reduce the amount of power that is consumed. For desktop computers, for example, conserving power reduces operating costs, while for laptop computers and other portable electronic devices, conserving power may extend battery life.
As laptop display screens, for example, continue to increase in size, such as 17 inch (43 cm) and larger screens, the impact on the battery life becomes more significant. Liquid Crystal Display (LCD) screens may include a backlight panel that is on when the display screen is on. One technique for conserving power is to reduce the brightness of the display screen or backlight panel. This power conservation method has the disadvantage that the dimmer display may degrade the visual experience of viewing the information for the user.
Since display screens may consume a significant portion of the power consumed by electronic display devices, other methods for reducing the amount of power consumed by display screens are desirable.
The following figures set forth embodiments in which like reference numerals denote like parts. Embodiments are illustrated by way of example and not by way of limitation in the accompanying figures.
There is provided herein a method for conserving illumination power of a display screen including: consuming power by displaying a larger illuminated image on the display screen and conserving power by reducing the size and increasing the resolution of the illuminated image on the display screen.
There is provided herein a display device including: a display screen having first region and second region, the first region having a first pixel density and the second region having a second pixel density, the second pixel density being higher than the first pixel density; an input for receiving image data; and a power source; wherein the display screen is operable in a full screen mode in which an image is displayed in both the first region and the second region and a reduced screen mode in which power to the first region is turned off and the image is displayed in the second region.
There is further provided herein a method of operating a display screen, the display screen in communication with a processor and a source of power, the method comprising: illuminating a first region and a second region of the display screen to display a first image, the second region having a higher pixel density than the first region; receiving, at the processor, a power conservation signal; and turning off power to the first region of the display screen in response to the power conservation signal; wherein illumination of the second region is continuous.
Referring to
The display screen 14 includes a first region 20 and a second region 22. In an LCD screen embodiment, the first region 20 includes a corresponding first EL portion (not shown) and the second region 22 includes a corresponding second EL portion (not shown) that is independently operable from the first EL portion. The second region 22 may be generally rectangular-shaped and may be located centrally within in the display screen 14. In the embodiment depicted in
The display screen 14 is operable in a full screen mode, in which illuminated images fill both the first region 20 and the second region 22, and a reduced screen mode, in which illuminated images fill the second region 22 only. Reduced screen mode also includes situations in which illuminated images fill part of the second region 22, and situations in which there may be some slight image spill-over into the first region 20. When operating in the full screen mode, the resolution of the display screen is less than or equal to a full screen maximum resolution, which is determined based on the first pixel density of the first region 20. In the full screen mode, images may appear seamless to the user so that the second region 22 is generally undetectable. When operating in the reduced screen mode, the resolution of the second region 22 is increased. Based on the respective pixel densities, the reduced screen maximum resolution is higher than the full screen maximum resolution. The reduced screen mode may conserve power by turning off power to the first region 20 and illuminating the second region 22 only only or illuminating part of the second region 22 or illuminating the second region 22 principally. “Turning off” power to the first region 20 may include completely shutting down all power to the first region 20 and may also include putting the first region 20 into a low-power or standby mode, or causing the first region to turn black or monochromatic or the like.
In one embodiment, the second region 22 has a pixel density 2× the pixel density of the first region 20. In another embodiment, the second region 22 has a pixel density that is more than 2×the pixel density of the first region 20.
The reduced screen mode is used to display high resolution images in a relatively small area. In one implementation, an image in regular resolution on the full screen can be comparable to ordinary display of images on the display screen, while displaying a high resolution image in the second region 22 can be comparable to displaying an image on a smaller portable, typically handheld, electronic device. In this way, displaying a high resolution image in the second region 22 can simulate the user experience when operating a handheld device, such as a smart phone or a PDA, for example. Because many users are accustomed to viewing handheld device screens, operating a larger screen display device 10 in a reduced screen mode is an easy transition. Some images may be more suited to display in a reduced screen mode than others. Such images may include video, electronic book images and e-mail message images, for example.
In one example, the first region 20 has a ppi corresponding to a 14 inch VGA screen. The first region 20 includes substantially 0.74 mega pixels, which is the standard 0.786 megapixel XGA screen less the second region 22. The second region 22 has a ppi substantially corresponding to a 3.25 inch XGA screen and includes 0.17 mega pixels. Thus, display screen 14 includes 0.91 megapixels, the sum of the pixels of regions 20 and 22.
Referring to
The processor 32 communicates with a Random Access Memory (RAM) (not shown) and a flash memory 34. An operating system 38, display driver 40 and software are typically stored in flash memory and are executable by the processor 32. The display driver 40 functions to translate software commands that are stored in memory 34 into commands for controlling the display device 10.
In the 14 inch VGA screen and 3.25 inch XGA screen example, while the display driver 40 is adapted to drive the 0.91 megapixel display screen 14, the pixel memory in display driver 40 need only be capable of rendering a 0.786 or smaller megapixel image. In the full screen mode, four adjacent pixels in the second region 22 can be redundantly driven by rendered image data corresponding to one pixel in first region 20, thus providing an XGA image have the same resolution in first and second regions 20, 22. In the reduced screen mode, the pixel memory in display driver 40 need only be capable of rendering 0.17 megapixel XGA image in second region 22, eliminating the redundant driving of pixels from the full screen mode and independently driving each pixel in second region 22.
The computer 30 includes computer executable programmed instructions for directing the computer 30 (or a tangible component of the computer 30 or a tangible device controlled by computer 30) to implement various applications. Some examples of applications that may be stored on and executed by the computer include: electronic messaging, games, calendar, address book and music player applications. It will be appreciated by a person skilled in the art that the flash memory may alternatively be a persistent storage, a Read-Only Memory (ROM) or other non-volatile storage. Some software components may alternatively be stored in RAM.
The processor 32 receives input from an input device 24, such as a keyboard, multifunction buttons, a touch pad, a touch screen, a mouse or a trackball, for example. The input device 24 may include a single device or more than one device. The computer 30 outputs image data to the display device 10 for display on the display screen 14. The processor 32 may further output to other devices (not shown) including an auxiliary display screen and a speaker, for example.
The display screen 14 switches between the full screen mode and the reduced screen mode when a signal (which will be referred to for convenience as a “power conservation signal”) is received by the processor 32. Power conservation signals may be generated when reduced screen-suitable images are to be displayed and the power to the first region 20 is turned off. For example, a power conservation signal may be generated when: an electronic book application is launched, an email message is opened or a video application is launched, for example. Launching of applications and opening of email messages is well known in the art. These operations may be performed by a user operating the input device 24. For example, an application may be launched by user selection of an application icon on a desktop or navigation through menus. Similarly, an email message may be opened when a user double clicks on a message using a mouse or highlights the message and selects “open” from a menu, for example.
Referring to
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As shown in
In another example, opening a movie could result a similar sequence of display size reduction, with the movie opened in a full screen user interface displayed corresponding to
Referring to
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It will be appreciated by a person skilled in the art that the display device 10 may be any device including a display screen of a typical display device including: a monitor for a desktop computer or an auxiliary monitor of a desktop or laptop or pad-type computer, a television, portable DVD player, a PDA or even a portable communication device such as a cell phone or pager where the image size is reduced while its resolution is increased to preserve power while facilitating an enhanced viewing experience.
In one embodiment, the brightness of the second region 22 may be dimmed to provide further power conservation for LCD screen applications.
In another embodiment, the first region 20 and the second region 22 are operated together, however, the second region 22 is operated at a resolution that is greater than the full screen maximum resolution. In one example, high resolution images may be displayed in the second region 22 while text is displayed in the first region 20.
The embodiments disclosed herein may reduce the amount of power consumed by a display screen when reduced screen-suitable images are displayed. By turning a portion of the screen illumination off during display of reduced screen-suitable images, less power may be consumed. These embodiments need not be exclusive of other power-saving techniques.
Although the concepts have been described herein as providing a potential benefit of power-saving, power-saving is not essential to the concepts. There conceivably may be circumstances in which the concepts described herein may provide no power-saving, and generation of the power conservation signal does not result in an actual conservation of power. Further, other potential benefits may be realized, including the ability to focus in on selected portions of an image, making details more visible at a high resolution, or making ready adaptation of small-screen-high-resolution software applications on a larger display screen.
Specific embodiments have been shown and described herein. However, modifications and variations may occur to those skilled in the art. All such modifications and variations are believed to be within the scope and sphere of the present embodiments.
Claims
1. A display device comprising:
- a display screen comprising a first region and second region, the first region comprising a first pixel density and the second region comprising a second pixel density, the second pixel density being higher than the first pixel density;
- an input for receiving image data; and
- a power source;
- wherein the display screen is operable in a full screen mode in which an image is displayed in both the first region and the second region and a reduced screen mode in which power to the first region is turned off and the image is displayed in the second region.
2. A display device as claimed in claim 1, wherein the display screen is a liquid crystal display (LCD) screen with a variable area electro luminescence (EL) backlight or a plasma display screen.
3. A display device as claimed in claim 1, wherein the image displayed in the second region has a higher resolution that the image of the full screen mode.
4. A display device as claimed in claim 1, wherein the second pixel density is at least two times higher than the first pixel density.
5. A display device as claimed in claim 1, wherein the input receives a cable for coupling the display device to a computer.
6. A display device as claimed in claim 1, wherein the input is for receiving wireless signals from a computer.
7. A display device as claimed in claim 1, wherein the input receives a power conservation signal for switching operation of the display screen from the full screen mode to the reduced screen mode.
8. A display device as claimed in claim 7, wherein the input is for receiving the power conservation signal from a user-operable input device.
9. A method of operating a display screen, the display screen in communication with a processor and a source of power, the method comprising:
- illuminating a first region and a second region of the display screen to display a first image, the second region having a higher pixel density than the first region;
- receiving, at the processor, a power conservation signal; and
- turning off power to the first region of the display screen in response to the power conservation signal;
- wherein illumination of the second region is continuous.
10. A method as claimed in claim 9, wherein the display screen is a liquid crystal display (LCD) screen with a variable area electro luminescence (EL) backlight or a plasma display screen.
11. A method as claimed in claim 9, wherein the first image has a first resolution and a second image displayed in the second region has a higher resolution that the first resolution.
12. A method as claimed in claim 9, wherein the second pixel density is 2 times higher than the first pixel density.
13. A method as claimed in claim 9, wherein the first image is displayed with a constant resolution in both the first region and the second region.
14. A computer-readable medium comprising instructions executable on the processor for implementing the method of claim 9.
Type: Application
Filed: Oct 19, 2010
Publication Date: Apr 19, 2012
Patent Grant number: 8698859
Inventor: Michael Joseph DeLuca (Boca Raton, FL)
Application Number: 12/907,829
International Classification: G09G 5/00 (20060101);